# Smoothing out values of an array

If I had an array of numbers such as [3, 5, 0, 8, 4, 2, 6], is there a way to “smooth out” the values so they’re closer to each other and display less variance?

I’ve looked into windowing the data using something called the Gaussian function for a 1-dimensional case, which is my array, but am having trouble implementing it. This thread seems to solve exactly what I need but I don’t understand how user naschilling (second post) came up with the Gaussian matrix values.

Context: I’m working on a music waveform generator (borrowing from SoundCloud’s design) that maps the amplitude of the song at time t to a corresponding bar height. Unfortunately there’s a lot of noise, and it looks particularly ugly when the program maps a tiny amplitude which results in a sudden decrease in height. I basically want to smooth out the bar heights so they aren’t so varied.

The language I'm using is Javascript.

EDIT: Sorry, let me be more specific about "smoothing out" the values. According to the thread linked above, a user took an array

``````[10.00, 13.00, 7.00, 11.00, 12.00, 9.00, 6.00, 5.00]
``````

and used a Gaussian function to map it to

``````[ 8.35,  9.35, 8.59,  8.98,  9.63, 7.94, 5.78, 7.32]
``````

Notice how the numbers are much closer to each other.

EDIT 2: It worked! Thanks to user Awal Garg's algorithm, here are the results:

No smoothing Some smoothing Maximum smoothing EDIT 3: Here's my final code in JS. I tweaked it so that the first and last elements of the array were able to find its neighbors by wrapping around the array, rather than calling itself.

``````var array = [10, 13, 7, 11, 12, 9, 6, 5];

function smooth(values, alpha) {
var weighted = average(values) * alpha;
var smoothed = [];
for (var i in values) {
var curr = values[i];
var prev = smoothed[i - 1] || values[values.length - 1];
var next = curr || values;
var improved = Number(this.average([weighted, prev, curr, next]).toFixed(2));
smoothed.push(improved);
}
return smoothed;
}

function average(data) {
var sum = data.reduce(function(sum, value) {
return sum + value;
}, 0);
var avg = sum / data.length;
return avg;
}

smooth(array, 0.85);
``````
• I'm not sure I understand what you mean smooth out values – Sterling Archer Sep 25 '15 at 18:54

Interesting question!

The algorithm to smooth out the values obviously could vary a lot, but here is my take:

``````"use strict";
var array = [10, 13, 7, 11, 12, 9, 6, 5];

function avg (v) {
return v.reduce((a,b) => a+b, 0)/v.length;
}

function smoothOut (vector, variance) {
var t_avg = avg(vector)*variance;
var ret = Array(vector.length);
for (var i = 0; i < vector.length; i++) {
(function () {
var prev = i>0 ? ret[i-1] : vector[i];
var next = i<vector.length ? vector[i] : vector[i-1];
ret[i] = avg([t_avg, avg([prev, vector[i], next])]);
})();
}
return ret;
}

function display (x, y) {
console.clear();
console.assert(x.length === y.length);
x.forEach((el, i) => console.log(`\${el}\t\t\${y[i]}`));
}

display(array, smoothOut(array, 0.85));``````

NOTE: It uses some ES6 features like fat-arrow functions and template strings. Firefox 35+ and Chrome 45+ should work fine. Please use the babel repl otherwise.

My method basically computes the average of all the elements in the array in advance, and uses that as a major factor to compute the new value along with the current element value, the one prior to it, and the one after it. I am also using the prior value as the one newly computed and not the one from the original array. Feel free to experiment and modify according to your needs. You can also pass in a "variance" parameter to control the difference between the elements. Lowering it will bring the elements much closer to each other since it decreases the value of the average.

A slight variation to loosen out the smoothing would be this:

``````"use strict";
var array = [10, 13, 7, 11, 12, 9, 6, 5];

function avg (v) {
return v.reduce((a,b) => a+b, 0)/v.length;
}

function smoothOut (vector, variance) {
var t_avg = avg(vector)*variance;
var ret = Array(vector.length);
for (var i = 0; i < vector.length; i++) {
(function () {
var prev = i>0 ? ret[i-1] : vector[i];
var next = i<vector.length ? vector[i] : vector[i-1];
ret[i] = avg([t_avg, prev, vector[i], next]);
})();
}
return ret;
}

function display (x, y) {
console.clear();
console.assert(x.length === y.length);
x.forEach((el, i) => console.log(`\${el}\t\t\${y[i]}`));
}

display(array, smoothOut(array, 0.85));``````

which doesn't take the averaged value as a major factor.

Feel free to experiment, hope that helps!

The technique you describe sounds like a 1D version of a Gaussian blur. Multiply the values of the 1D Gaussian array times the given window within the array and sum the result. For example

1. Assuming a Gaussian array {.242, .399, .242}
2. To calculate the new value at position n of the input array - multiply the values at n-1, n, and n+1 of the input array by those in (1) and sum the result. eg for [3, 5, 0, 8, 4, 2, 6], n = 1:

n1 = 0.242 * 3 + 0.399 * 5 + 0.242 * 0 = 2.721

You can alter the variance of the Gaussian to increase or reduce the affect of the blur.

• This is so close to what I'm looking for. How did you come up with the Gaussian array [.242, .399, .242]? – robinnnnn Sep 25 '15 at 20:11
• They are discrete values of the Gaussian function with (mean 0, sd = 1) at -1, 0, and 1. – copeg Sep 25 '15 at 20:17
• Sorry, but can you be more specific as to how those can be calculated? I'm assuming you used this function. I understand where the mean and standard deviation goes; for x did you plug in -1, 0 and 1? – robinnnnn Sep 25 '15 at 20:48